Abstract #1653, 224th ECS Meeting, © 2013 The Electrochemical Society Nickel-cerium alloys for borohydride oxidation References 1. D. M. F. Santos, C. A. C. Sequeira, Sodium D.M.F. Santosa, , B. Sljukica, D. Macciòb, A. Sacconeb, a borohydride as a fuel for the future, Renew. Sustain. ∗ C.A.C. Sequeira Energy Rev. 15 (2011) 3980. a Materials Electrochemistry Group, Institute of Materials 2. D. M. F. Santos, C. A. C. Sequeira, Cyclic voltammetry and Surfaces Science and Engineering, Instituto Superior investigation of borohydride oxidation at a gold electrode, Técnico, TU Lisbon, 1049-001 Lisboa, Portugal Electrochim. Acta 55 (2010) 6775. b 3. J. Ma, N. A. Choudhury, Y. Sahai, A comprehensive Università degli Studi di Genova, Dipartimento di review of direct borohydride fuel cells, Renew. Sustain. Chimica e Chimica Industriale (DCCI), via Dodecaneso Energy Rev. 14 (2010) 183. 31, I-16146 Genova, Italy 4. D. M. F. Santos, P. G. Saturnino, D. Macciò, A. Saccone, C. A. C. Sequeira, Platinum-rare earth intermetallic alloys as anode electrocatalysts for Sodium borohydride (NaBH4) is being actively borohydride oxidation. Catal. Today 170 (2011) 134. investigated in the last decade as an anodic fuel for direct borohydride fuel cells (DBFCs) [1]. The main reasons for that is because the solid state NaBH4 is chemically stable and can be easily stored and distributed, the oxidation product, sodium metaborate (NaBO2) is non-toxic and can be recycled back to NaBH4, and there are no gaseous pollutants exhausted from the cell reactions. Moreover, the DBFC presents higher energy density than the direct methanol fuel cell. Noble metal electrodes, namely gold (Au) and its alloys, display a rather good borohydride oxidation activity but their high cost makes them unsuitable for - widespread applications [2]. Au promotes complete BH4 oxidation with 8 electrons exchanged (Eq. 1). - - - - BH4 + 8 OH → BO2 + 6 H2O + 8 e (1) However, most electrode substrates also promote - the competitive BH4 hydrolysis reaction (Eq. 2) that reduces the overall coulombic efficiency of the process. - - BH4 + 2 H2O → BO2 + 4 H2 (2) For instance, nickel (Ni) electrodes present - reasonable activity for BH4 oxidation but their - simultaneous catalytic effect towards the BH4 hydrolysis leads to an overall number of exchanged electrons in the oxidation process between 2 and 4, instead of desirable value of 8 [3]. It has been recently shown that presence of rare earth (RE) elements in intermetallic alloy electrodes - changes the electrode’s activity for BH4 oxidation and hydrolysis and consequently alters reaction mechanism and main kinetic parameters [4]. Among other factors, these changes will depend on the composition of the alloying elements as well as on the applied anodic potential range. In this paper, Ni and Ni-cerium (Ce) intermetallic alloy electrodes with different amounts of - Ce (5 and 10 at.% Ce) are studied for BH4 oxidation in alkaline media by cyclic voltammetry (CV), chronopotentiometry (CP), and chronoamperometry (CA), in the temperature range 25 - 55 ºC. Electrochemical data are modeled to obtain - relevant kinetic parameters of BH4 oxidation at these electrodes, such as number of exchanged electrons, anodic charge transfer coefficient, and standard rate constant. Effect of electrolyte composition and temperature on the evaluated parameters has been investigated as well. Arrhenius plots are used to estimate the activation energies. .
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